FAQ

The invention of carbon fiber was the result of collaborative efforts by researchers in the UK and the US. Starting in the late 1950s, scientists and engineers, including Roger Bacon, W. Watt, R. Trent, and Dr. Frederick Brooks Jr., developed the material through experimentation and research. The breakthrough came with the creation of a new commercial carbon fiber called "T-300" by Brooks and his team at DuPont in the 1970s. Since then, carbon fiber technology has continued to advance, leading to new and improved materials with diverse applications.

No, carbon fiber does not melt since it undergoes a chemical change when heated rather than a physical change. It burns or decomposes above 400 °C (752 °F) instead of melting, losing its strength and stiffness. Specialized processes are used to shape or join carbon fibers to avoid damage caused by heat.

Carbon fiber has a high ignition temperature, typically above 400 degrees Celsius (752 degrees Fahrenheit), and doesn't easily catch fire. When ignited, it tends to char instead of burning. However, it is still essential to take precautions when working with carbon fiber composites, which can contain resins and other materials that may be flammable.

The cost of carbon fiber can vary depending on the quality, quantity, and application of the material. On average, carbon fiber can cost anywhere from $10 to $50 per kilogram, but prices can exceed $100 per kilogram for high-end carbon fiber materials.

The high cost of carbon fiber is due to the complex manufacturing process and expensive raw materials. Carbon fiber production involves several steps that require specialized equipment and skilled technicians, and the raw materials used to make carbon fiber, such as PAN, are expensive. Due to its high cost, carbon fiber is most commonly used in high-performance industries such as aerospace, defense, automotive, and sporting goods

Carbon fiber is a fibrous material made from carbon-based synthetic fibers, and plastic is a synthetic material made from various organic polymers. Both materials are often combined to create a strong, stiff, and flexible hybrid composite material that has numerous advantages for various industries.

Carbon fiber can be destroyed by impact damage, high temperatures, and prolonged exposure to corrosive substances or UV light. To maintain its durability, carbon fiber should be handled with care, kept away from damaging substances, and protected from impacts and stress.

Carbon fiber can fail due to manufacturing defects, improper handling, high temperatures, corrosion, and impact damage. However, with proper handling, design, testing, and maintenance, carbon fiber can offer exceptional strength and durability for many applications.

Carbon fiber is strong, but can be weakend by manufacturing defects, improper handling, high temperatures, corrosive substances, and severe impacts. Carbon fiber is a high-performance material that requires careful handling and maintenance to preserve its strength and durability

Carbon fiber is used in Formula One cars due to its high strength-to-weight ratio, stiffness, impact resistance, and low weight, making it ideal for constructing the monocoque chassis, bodywork, and suspension components. It helps F1 teams meet the weight and performance regulations while ensuring speed, maneuverability, and safety during high-speed racing.